JP2015154151A - Relay device, priority control method, and computer program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform priority control on the basis of each network identifier, when a plurality of network identifiers are used in an environment of mutual interference.SOLUTION: A relay device, which uses the plurality of network identifiers in the environment of mutual interference, includes: a calculation unit for calculating a communicable period of each communication device to be connected to a network identifier which is set priority-by-priority, on the basis of a rate of a communicable period in a predetermined period which is set priority-by-priority; a generation unit for generating a control signal using the calculated communicable period; and a transmitter unit for transmitting the generated control signal to a communication device.

Description

  The present invention relates to priority control technology.

  With the spread of smartphones, mobile networks have become mainstream in recent years, and fixed networks using wireless local area networks (for example, Wi-Fi (registered trademark) (Wireless Fidelity)) to reduce traffic on mobile networks Data offload to is promoted. The Wi-Fi standard includes IEEE (The Institute of Electrical and Electronics Engineers) 802.11a / b / n / ac and the like, and it is theoretically possible to perform ultrahigh-speed communication of 6.93 Gbps at maximum. In addition, the technologies disclosed in Patent Documents 1 and 2 can support priority control suitable for the communication state (application, traffic, etc.) of a communication terminal using a wireless LAN, so that high-speed data off from the mobile network to the fixed network is possible. Loading is feasible.

JP 2007-235782 A JP 2012-134893 A

  However, in Patent Documents 1 and 2, although priority control suitable for the communication state of the entire wireless LAN in an environment where a plurality of access points interfere with each other is possible, a plurality of SSIDs (Service Set IDentifiers) exist in an environment where the access points interfere with each other. When used, priority control for each SSID cannot be performed. For this reason, when a service such as FON that makes a GW (Gate Way) available by opening up a wireless LAN relay device (hereinafter referred to as “GW”) to an external user, communication is primarily given priority. There is a problem of adversely affecting the communication of the owner of the GW to be performed. Such a problem is not limited to SSID, but is common to all communications using a plurality of network identifiers in an environment where they interfere with each other.

  In view of the above circumstances, an object of the present invention is to provide a technique capable of performing priority control for each network identifier when a plurality of network identifiers are used in an environment where they interfere with each other.

  One aspect of the present invention is a relay device that uses a plurality of network identifiers in an environment that interferes with each other, and the communication possible period for each communication device connected to the network identifier set for each priority is defined as the priority. A calculation unit that calculates based on a ratio of a communicable period in a predetermined period set for each, a generation unit that generates a control signal using the calculated communicable period, and the generated control signal And a transmission unit that transmits to the communication device.

  One aspect of the present invention is the relay device described above, in which the calculation unit calculates a communicable period for each priority by multiplying the predetermined period and the communicable ratio, and The communicable period for each communication apparatus is calculated for each priority by dividing the communicable period calculated in (1) by the number of connected communication apparatuses for each priority.

  One aspect of the present invention is the relay device described above, in which the calculation unit calculates a communicable period for each priority by multiplying the predetermined period and the communicable ratio, and The communicable period calculated for the communication apparatus is calculated for each priority based on the communication state of the communication apparatus for each priority.

  One aspect of the present invention is a priority control method in a relay apparatus that uses a plurality of network identifiers in an environment that interferes with each other, and includes a communication possible period for each communication apparatus connected to the network identifier set for each priority. A calculation step of calculating based on a ratio of a communicable period in a predetermined period set for each priority, a generation step of generating a control signal using the calculated communicable period, and the generated And a transmission step of transmitting a control signal to the communication device.

  One aspect of the present invention is a computer program in a relay apparatus that uses a plurality of network identifiers in an environment that interferes with each other, and the communication possible period for each communication apparatus that is connected to the network identifier set for each priority. A calculation step for calculating based on a ratio of a communicable period in a predetermined period set for each priority, a generation step for generating a control signal using the calculated communicable period, and the generated control A computer program for causing a computer to execute a transmission step of transmitting a signal to the communication device.

  The present invention makes it possible to perform priority control for each network identifier when a plurality of network identifiers are used in an environment where they interfere with each other.

It is a figure which shows the system configuration | structure of the priority control system 100 in this invention. It is a schematic block diagram showing the function structure of GW10 in this embodiment. It is a figure showing the specific example of a priority control table. It is a figure showing the specific example of the frame format of a transmission permission response. It is a figure which shows the example of a display of a setting registration screen. It is a flowchart which shows the flow of a calculation process of the communication possible time of GW10 in this embodiment. It is a flowchart which shows the flow of the transmission process of the transmission permission signal of GW10 in this embodiment. It is a sequence diagram which shows operation | movement of the priority control system 100 in this embodiment. It is a sequence diagram which shows operation | movement of the priority control system 100 in this embodiment. It is a flowchart which shows the flow of a calculation process of the communication possible time of GW10 in this embodiment. It is a sequence diagram which shows operation | movement of the priority control system 100 in this embodiment. It is a sequence diagram which shows operation | movement of the priority control system 100 in this embodiment. It is a sequence diagram which shows the specific operation | movement of the setting change process of the priority control table in this embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a system configuration of a priority control system 100 according to the present invention. The priority control system 100 of the present invention includes a GW 10 and a target server 20. To the priority control system 100, a communication device 30-1-30-N (N is an integer of 2 or more) and an operator terminal 40 are connected. In the following description, the communication device 30-1-30-N will be referred to as the communication device 30 unless otherwise distinguished.

  The GW 10 is a wireless LAN access point, and communicates with the communication device 30 by wireless LAN connection. For example, Wi-Fi is used for the wireless LAN connection. The GW 10 provides the communication device 30 with connection to the network 50, for example, access to the target server 20 through the network 50. Further, the GW 10 communicates with the operator terminal 40. The GW 10 can use a plurality of SSIDs in an environment where they interfere with each other. The environment that interferes with each other is an environment in which a plurality of communication devices 30 connected to the GW 10 transmit signals of substantially the same frequency and substantially the same channel using different SSIDs. The GW 10 operates in a plurality of modes (for example, a first mode and a second mode). The operation mode of the GW 10 can be changed by a GW related person operating the operator terminal 40. A GW related person is a person who should be given priority primarily to communication via the GW 10 such as the owner of the GW 10 or the related person of the owner of the GW 10.

The target server 20 is configured using an information processing apparatus. The target server 20 is a server to which the communication device 30 desires connection.
The communication device 30 is configured using an information processing device such as a smartphone, a tablet terminal, a mobile phone, a personal computer, a notebook computer, or a game machine. The communication device 30 performs communication with the GW 10. The communication device 30 transmits a transmission permission request to the GW 10. The transmission permission request is a signal used to request data transmission permission from the GW 10. The transmission permission request is, for example, an RTS (request to send) frame.

The operator terminal 40 is configured using an information processing device such as a personal computer. The operator terminal 40 is operated by a GW related person when changing the setting of the GW 10.
The network 50 may be a network configured in any way. For example, the network 50 may be configured using the Internet.

FIG. 2 is a schematic block diagram showing a functional configuration of the GW 10 in the present embodiment.
The GW 10 includes a CPU (Central Processing Unit), a memory, an auxiliary storage device, and the like connected by a bus, and executes a priority control program. By executing the priority control program, the GW 10 has the first communication unit 101, the control unit 102, the priority control information storage unit 103, the connection terminal monitoring unit 104, the calculation unit 105, the signal generation unit 106, the second communication unit 107, and the relay unit. 108, functions as an apparatus including the setting registration screen data storage unit 109. Note that all or part of the functions of the GW 10 may be realized by using hardware such as an application specific integrated circuit (ASIC), a programmable logic device (PLD), or a field programmable gate array (FPGA). The priority control program may be recorded on a computer-readable recording medium. The computer-readable recording medium is, for example, a portable medium such as a flexible disk, a magneto-optical disk, a ROM, a CD-ROM, or a storage device such as a hard disk built in the computer system. The priority control program may be transmitted / received via a telecommunication line.

The first communication unit 101 communicates with the communication device 30. For example, the first communication unit 101 receives a transmission permission request transmitted from the communication device 30. For example, the first communication unit 101 transmits a transmission permission response to the communication device 30. The transmission permission response is a response for notifying the communication device 30 that is the transmission source of the transmission permission request that the data transmission is permitted. The transmission permission response is, for example, a CTS (clear to send) frame.
The control unit 102 controls each functional unit of the GW 10.

The priority control information storage unit 103 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device. The priority control information storage unit 103 stores a priority control table. The priority control table is a table in which control information for each priority is registered. For example, an SSID is associated with each priority in the priority control table.
The connection terminal monitoring unit 104 monitors the communication device 30 connected to the own device. For example, the connection terminal monitoring unit 104 monitors whether there is a communication device 30 connected to the own device by referring to the priority control table.

The calculation unit 105 calculates a communicable period for each priority based on the priority control table. That is, the calculation unit 105 calculates a communicable period for each SSID. The communicable period represents a period during which the communication device 30 can communicate with the target server 20 via the GW 10. Further, the calculation unit 105 further distributes the value of the communicable period calculated for each priority according to the operation mode of the own device, thereby communicating for each communication device 30 connected to the SSID set for each priority. Calculate the possible period. Specific processing of the calculation unit 105 will be described later.
The signal generation unit 106 generates a transmission permission response in response to the transmission permission request transmitted from the communication device 30. When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period calculated by the calculation unit 105 in the header portion.

The second communication unit 107 communicates with the target server 20.
The relay unit 108 relays communication performed between the communication device 30 and the target server 20. For example, the relay unit 108 relays data transmitted from the target server 20 to the communication device 30 and data transmitted from the communication device 30 to the target server 20.
The setting registration screen data storage unit 109 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device. The setting registration screen data storage unit 109 stores screen data for performing setting registration of the GW 10 (hereinafter referred to as “setting registration screen data”).

FIG. 3 is a diagram illustrating a specific example of the priority control table stored in the priority control information storage unit 103. The priority control table has a plurality of records representing control information for each priority. The record has each value of priority, communication ratio, SSID, number, MAC_STA, and communicable time.
The priority represents a priority order when the communication device 30 performs communication. In FIG. 3, “high priority”, “medium priority”, and “low priority” are shown as specific examples of priorities. “High priority” indicates that the priority is high. “Medium priority” indicates that the priority is neither high nor low. “Low priority” indicates that the priority is low. The communication ratio represents a ratio of a communicable period within a predetermined period (for example, 1 second). The SSID represents a network identification name set in the GW 10. The number represents information for identifying the number of communication devices 30 connected to the GW 10 for each priority. MAC_STA represents the MAC address of the communication device 30 connected to the GW 10. The communicable period represents a period during which the communication device 30 can communicate. In the specific example of FIG. 3, “sec (seconds)” is set as the unit of the communicable period.

  In the example shown in FIG. 3, three priorities are registered in the priority control table. These three priorities are “high priority”, “medium priority”, and “low priority”. In FIG. 3, the uppermost row (“high priority” row) of the priority control table has a communication ratio value of “0.6”, an SSID value of “SSID1”, a number value of “1”, “ 2 ”,“ 3 ”, MAC_STA values are“ AAA ”,“ BBB ”,“ CCC ”, and communication possible period values are“ 0-0.2 ”,“ 0.2-0.4 ”,“ 0. 4 to 0.6 ". That is, the ratio of the communicable period in a predetermined period (for example, 1 second) of the communication device 30 connected to the high priority SSID “SSID1” is “0.6”, and the MAC address is included in the high priority SSID. Three communication devices 30 identified by “AAA”, “BBB”, and “CCC” are connected, and the communication possible period of each communication device 30 is “between 0 and 0.2 seconds”, “0” .Between 2 and 0.4 seconds "and" between 0.4 and 0.6 seconds ". The high-priority SSID is an SSID that is often used when the communication device 30 of the GW-related person connects to the GW 10 and represents an SSID that enables high-priority communication. Hereinafter, the SSID that enables high priority communication is referred to as “high priority SSID”. The communication device 30 connected to the high priority SSID is referred to as a high priority device.

  In FIG. 3, the second row (“medium priority” row) of the priority control table has a communication ratio value of “0.3”, an SSID value of “SSID2”, and a number value of “1”. ”,“ 2 ”, MAC_STA values are“ DDD ”and“ EEE ”, and communication possible period values are“ 0.60 to 0.75 ”and“ 0.75 to 0.9 ”. That is, the ratio of the communicable period in the predetermined period of the communication device 30 connected to the medium priority SSID “SSID2” is “0.3”, and the medium priority SSID includes MAC addresses “DDD” and “EEE”. Are connected, and the communication possible period of each communication device 30 is “between 0.60 and 0.75 seconds” and “0.75 to 0.9 seconds. It is shown that it is “between”. The medium priority SSID represents an SSID that enables medium priority communication. Hereinafter, the SSID that enables medium priority communication is referred to as “medium priority SSID”. Further, the communication device 30 connected to the medium priority SSID is referred to as a medium priority device.

  In FIG. 3, the third row (“low priority” row) of the priority control table has a communication ratio value of “0.1”, an SSID value of “SSID3”, and a number value of “1”. “, The value of MAC_STA is“ FFF ”, and the value of the communicable period is“ 0.9 to 1.0 ”. That is, the ratio of the communicable period in the predetermined period of the communication device 30 connected to the low priority SSID “SSID3” is “0.1”, and the low priority SSID is identified by the MAC address “FFF”. It is indicated that one communication device 30 is connected, and the communicable period of the communication device 30 is “between 0.9 and 1.0 seconds”. The low-priority SSID is an SSID that is often used when the communication device 30 of the external user connects to the GW 10 and represents an SSID that enables low-priority communication. The external user is the communication device 30 of a user other than the GW related person. Hereinafter, an SSID that enables low-priority communication in this way is referred to as a “low-priority SSID”. Further, the communication device 30 connected to the low priority SSID is referred to as a low priority device.

  In addition, each value of a priority, a communication ratio, and SSID is changed suitably, when a GW relevant person operates the operator terminal 40. FIG. Further, the number and each value of MAC_STA are appropriately changed according to the communication device 30 connected to the GW 10. As the communicable period, the value of the communicable period calculated by the calculation unit 105 is registered.

Next, the processing of the calculation unit 105 will be described with a specific example.
First, the calculation unit 105 multiplies the value of the communication ratio registered in the priority control table by the value of a predetermined period (for example, 1 second) to determine the communicable period within the predetermined period for each priority. calculate. For example, the calculation unit 105 calculates a communication ratio value (for example, “0.6”) at the priority “high priority” registered in the priority control table and a predetermined period (for example, “1 second”). To calculate the communicable period “0.6” at the priority “high priority”. Further, the calculation unit 105 calculates a communication ratio value (for example, “0.3”) at the priority “medium priority” registered in the priority control table and a predetermined period (for example, “1 second”). To calculate the communicable period “0.3” at the priority “medium priority”. In addition, the calculation unit 105 calculates a communication ratio value (for example, “0.1”) at the priority “low priority” registered in the priority control table and a value for a predetermined period (for example, “1 second”). To calculate the communicable period “0.1” at the priority “low priority”. Through the processing described above, the calculation unit 105 calculates a communicable period for each priority in a predetermined period.

Thereafter, the calculation unit 105 uses a communicable period calculated for each priority within a predetermined period (for example, “1 second”) in order of high priority (high priority → middle priority → low priority). The communication possible period in is assigned for each priority. For example, the calculation unit 105 assigns a communicable period as follows. In the example described above, since the communicable period at the priority “high priority” is “0.6 seconds”, the calculation unit 105 first sets “0 to 0.6 in a predetermined period (for example,“ 1 second ”). A period of “second” is assigned to a communicable period of priority “high priority”. “0 to 0.6 seconds” represents that data can be transmitted to and received from the target server 20 for “0 to 0.6 seconds” after the communication device 30 receives the signal. In the above-described example, since the communicable period with the priority “medium priority” is “0.3 seconds”, the calculation unit 105 next selects “0” within a predetermined period (for example, “1 second”). .6 to 0.9 seconds "is assigned to the communication possible period with the priority" medium priority ". “0.6 to 0.9 seconds” means that data can be transmitted to and received from the target server 20 for “0.6 to 0.9 seconds” after the communication device 30 receives the signal. Represents. In the above-described example, since the communicable period with the priority “low priority” is “0.1 second”, the calculation unit 105 sets “0.9” within a predetermined period (for example, “1 second”). A period of ˜1.0 seconds is assigned to a communicable period of priority “low priority”. “0.9 to 1.0 second” means that data can be transmitted to and received from the target server 20 for “0.9 to 1.0 second” after the communication device 30 receives the signal. Represents.
Through the processing described above, the calculation unit 105 assigns a communicable period for each priority.

Next, a description will be given of a process in which the calculation unit 105 calculates the communicable period for each communication device 30 by distributing the communicable period assigned for each priority according to the operation mode of the own device.
First, a case where the GW 10 is operating in the first mode will be described. When the GW 10 is operating in the first mode, the calculating unit 105 connects the value of the communicable period assigned for each priority to the SSID set in association with each priority. By dividing by the number of units, the communicable period for each communication device 30 is calculated for each priority. For example, when there are a plurality of high-priority devices (for example, three), the calculation unit 105 is a value of a communicable period (“0 to 0.6 seconds” in the above example) assigned to the priority “high priority”. Is divided by the number of high-priority devices to calculate a communicable period for each high-priority device. In this example, the communicable periods of the high priority devices are “0 to 0.2 seconds”, “0.2 to 0.4 seconds”, and “0.4 to 0.6 seconds”, respectively. The calculation unit 105 assigns the calculated communicable period to each high priority device. The order of allocation may be the order in which the communication is possible in the order in which the registered order is early (number value is small), or the other order. In the case of the priority “medium priority” and “low priority”, as in the case of the priority “high priority”, the calculation unit 105 calculates the communicable period for each communication device 30, and the calculated communicable period is used as the communication device 30. Assign every.
This is the end of the description of the case where the GW 10 is operating in the first mode.

A case where the GW 10 is operating in the second mode will be described. When the GW 10 is operating in the second mode, the calculation unit 105 uses the communication possible period value assigned for each priority as the communication possible period for each communication apparatus 30 based on the communication state of the communication apparatus 30 for each priority. Is calculated for each priority. For example, EDCA (Enhanched Distributed Channel Access) priority control technology is used. Specifically, first, the calculation unit 105 multiplies the number of communication devices 30 for each access category of the main communication of the communication device 30 connected to the own device by the traffic amount of each communication device 30. Next, the calculation unit 105 determines the EDCA parameters AIES, Cw _max , and Cw _min for each access category based on the number of each access category, and uses the determined parameters to determine the communication possible period for each access category. calculate. The calculation unit 105 executes this process for each priority. Thereafter, the calculation unit 105 calculates a communicable period for each communication device 30 and assigns the calculated communicable period to each communication device 30.
This is the end of the description of the case where the GW 10 is operating in the second mode.

FIG. 4 is a diagram illustrating a specific example of a frame format of a transmission permission response transmitted by the GW 10.
The transmission permission response includes a header area, a payload area, and an FCS (Frame Check Sequence). The header area includes fields for storing values of a PLCP (physical layer convergence protocol) preamble, a PLCP header, and an IEEE (The Institute of Electrical and Electronics Engineers) 802.11 header. The payload area is composed of fields for storing data.

  The PLCP preamble field is a field in which information on the bit string of the synchronization signal is stored. The field of the PLCP header is a field in which information such as a modulation scheme and a data length is stored. The IEEE 802.11 header is composed of fields for storing values of frame control, Duration / ID, period information, first address, second address, third address, sequence control, and fourth address. The frame control field is a field that stores information such as the type of frame, the destination of the frame, whether the transmission source is wireless or wired, and fragment information. The Duration / ID field is a field in which information on Duration or ID is stored. The period information field is a field for notifying the communication apparatus 30 of a communicable period. In the present embodiment, the value of the communicable period calculated by the calculation unit 105 is stored in the period information field. The fields of the first address, the second address, the third address, and the fourth address are fields for storing information such as the destination MAC address and the source MAC address. The sequence control field is a field in which information such as a sequence number of data to be transmitted is stored.

FIG. 5 is a diagram illustrating a display example of the setting registration screen.
The setting registration screen shown in FIG. 5 is displayed on the Web browser of the operator terminal 40 when the operator terminal 40 requests setting registration screen data from the GW 10 in response to an operation by a GW related person. In the setting registration screen shown in FIG. 5, a mode setting area 70, a setting completion button 71, a priority control information setting area 72, a setting completion button 73, and a completion button 74 are displayed.

  The mode setting area 70 is an area for setting the operation mode of the GW 10. When the GW related person operates the operator terminal 40 and selects the mode setting area 70, a changeable operation mode (for example, the first mode and the second mode) is displayed in a pull-down manner. The GW related person selects an operation mode desired to be set in the GW 10 from a plurality of operation modes displayed in a pull-down display. Thereafter, the selected operation mode is displayed in the mode setting area 70. The setting completion button 71 is a button used for completing the setting of the operation mode. When the setting completion button 71 is selected, the setting of the operation mode of the GW 10 is completed. That is, the operation mode displayed in the mode setting area 70 is set to the operation mode of the GW 10.

  The priority control information setting area 72 is an area for setting information for each priority. The priority, the communication ratio, and the SSID value are appropriately changed by the GW related parties. In the SSID field, one or a plurality of SSIDs are registered for each priority. However, the same SSID cannot be set for items of different priorities. The setting completion button 73 is a button used for setting information for each priority. When the setting completion button 73 is selected, the setting of information for each priority of the GW 10 is completed. That is, information for each priority displayed in the priority control information setting area 72 is set in the priority control table. The completion button 74 is a button used when input of setting contents is completed. When the completion button 74 is pressed, the contents set in the mode setting area 70 and the priority control information setting area 72 are transmitted to the GW 10.

FIG. 6 is a flowchart showing the flow of processing for calculating the communicable time of the GW 10 in this embodiment. Note that FIG. 6 illustrates an example in which the GW 10 is operating in the first mode.
The connection terminal monitoring unit 104 refers to the priority control table and confirms the connection of the communication device 30 to the own device (step S101). When the connection to the own device is confirmed, the connection terminal monitoring unit 104 notifies the calculation unit 105 to that effect. The calculation unit 105 calculates a communicable period within a predetermined period for each priority based on the priority control table (step S102). Thereafter, the calculation unit 105 assigns a communicable period within the calculated predetermined period for each priority. The connected terminal monitoring unit 104 refers to the priority control table and checks the number of high priority devices (step S103). The calculation unit 105 calculates a communicable period according to the number of high priority devices (step S104). Specifically, the calculation unit 105 divides the value of the high-priority communicable period among the communicable periods assigned for each priority in the process of step S102 by the number of high-priority apparatuses. The communication possible period is calculated for each. Thereafter, the calculation unit 105 assigns the communicable period calculated in step S104 to each high priority device. The calculation unit 105 records the value of the communicable period assigned to each high priority device in the priority control table.

  Further, the connected terminal monitoring unit 104 refers to the priority control table and confirms the number of medium priority devices (step S105). The calculating unit 105 calculates a communicable period according to the number of medium priority devices (step S106). Specifically, the calculation unit 105 divides the value of the medium priority communicable period among the communicable periods allocated for each priority in the process of step S102 by the number of medium priority apparatuses. The communication possible period is calculated for each. Thereafter, the calculation unit 105 assigns the communicable period calculated in the process of step S106 to each medium priority device. The calculation unit 105 records the value of the communicable period assigned to each medium priority device in the priority control table.

  Further, the connected terminal monitoring unit 104 refers to the priority control table and confirms the number of low priority devices (step S107). The calculation unit 105 calculates a communicable period according to the number of low priority devices (step S108). Specifically, the calculation unit 105 divides the value of the low-priority communicable period among the communicable periods assigned for each priority in the process of step S102 by the number of low-priority apparatuses. The communication possible period is calculated for each. Thereafter, the calculation unit 105 assigns the communicable period calculated in the process of step S108 to each low priority device. The calculation unit 105 records the value of the communicable period assigned to each low priority device in the priority control table.

FIG. 7 is a flowchart showing a flow of transmission processing of a transmission permission signal of the GW 10 in the present embodiment. Note that the transmission processing of the transmission permission signal is the same when the GW 10 is operating in either the first mode or the second mode.
The first communication unit 101 receives the transmission permission request transmitted from the communication device 30 (step S201). The connection terminal monitoring unit 104 refers to the priority control table and determines whether there is a communication device 30 (hereinafter, referred to as “influenced device”) that affects the communication device 30 that is the transmission source of the transmission permission request ( Step S202). The communication device 30 that has an influence on the communication device 30 that is the transmission source of the transmission permission request is the communication device 30 that is connected to the same SSID as the communication device 30 that is the transmission source of the transmission permission request. If there is no influential device (step S202—NO), the signal generation unit 106 generates a transmission permission response to the communication device 30 that is the transmission source of the transmission permission request (step S203). Specifically, first, the signal generation unit 106 refers to the priority control table and selects a record corresponding to the MAC address of the communication device 30 that is the transmission source of the transmission permission request. Next, the signal generation unit 106 acquires the value recorded in the item of the communicable period of the selected record. Then, the signal generation unit 106 generates a transmission permission response by storing the acquired value in the header. Thereafter, the first communication unit 101 transmits the generated transmission permission response to the communication device 30 that is the transmission source of the transmission permission request (step S204).

In the process of step S202, when an affected device exists (step S202-YES), the signal generation unit 106 generates a transmission permission response for the communication device 30 that is the transmission source of the transmission permission request (step S205). Thereafter, the first communication unit 101 transmits the generated transmission permission response to the communication device 30 (step S206). The control unit 107 determines whether a transmission permission response has been transmitted to all the affected devices (step S207). When the transmission permission response is transmitted to all the affected devices (step S207—YES), the processing of the GW 10 ends.
On the other hand, if the transmission permission response has not been transmitted to all the affected devices (step S207—NO), the signal generation unit 106 generates a transmission permission response for the affected device (step S208). Specifically, first, the signal generation unit 106 refers to the priority control table and selects a record corresponding to the MAC address of the affected device. Next, the signal generation unit 106 acquires the value recorded in the item of the communicable period of the selected record. Then, the signal generation unit 106 generates a transmission permission response by storing the acquired value in the header. The first communication unit 101 transmits the generated transmission permission response to the affected device (step S209). Thereafter, the processing after step S207 is repeatedly executed.

8 and 9 are sequence diagrams showing the operation of the priority control system 100 in the present embodiment. In the description of FIGS. 8 and 9, a case where the GW 10 operates in the first mode will be described as an example. At the start of the process, no GW 10 is connected.
First, the first communication unit 101 of the GW 10 broadcasts a beacon (high priority SSID) to each communication device (communication devices 30-1 and 30-2) (steps S301 and 302).
The communication device 30-1 receives a beacon (high priority SSID) issued from the GW 10. The communication device 30-1 makes a probe request to the GW 10 for the SSID (high priority SSID) set in the own device (communication device 30-1) (step S303).

  The first communication unit 101 of the GW 10 receives the probe request transmitted from the communication device 30-1. The connected terminal monitoring unit 104 refers to the priority control table and determines whether the probe-requested high priority SSID and the broadcast high priority SSID are the same. When the high priority SSID requested for the probe and the broadcast high priority SSID are the same, the first communication unit 101 makes a probe response to the communication device 30-1 (step S304). When the high priority SSID requested for the probe is different from the broadcast high priority SSID, the first communication unit 101 does not make a probe response.

  The communication device 30-1 receives the probe response transmitted from the GW 10. Upon receiving the probe response, the communication device 30-1 performs authentication with the GW 10. Specifically, the communication device 30-1 transmits a high priority SSID password to the GW 10 according to an authentication method (for example, a password) set in advance with the GW 10 (step S305).

  The first communication unit 101 receives the password of the high priority SSID transmitted from the communication device 30-1. The control unit 102 determines whether or not the received high priority SSID password matches a preset high priority SSID password. If the passwords match, the first communication unit 101 transmits a notification indicating the completion of authentication to the communication device 30-1. If the passwords are different, the first communication unit 101 transmits an error to the communication device 30-1 (step S306).

  When the authentication is completed, the communication device 30-1 transmits an association request to the GW 10 (step S307). The first communication unit 101 receives the association request transmitted from the communication device 30-1. The first communication unit 101 transmits an association response to the communication device 30-1 as a response to the received association request (step S308). Thereby, connection with GW10 and the communication apparatus 30-1 is completed.

  When the connection is completed, the control unit 102 records information (for example, a MAC address) of the communication device 30-1 for which the connection is completed in the priority control table. More specifically, the control unit 102 records information of the communication device 30-1 in a record of the priority control table corresponding to the SSID (high priority SSID) included in the received association request. The connection terminal monitoring unit 104 checks the number of communication devices 30 connected to the own device by referring to the priority control table (step S309).

  The calculation unit 105 calculates a communicable period for each priority, and assigns the calculated communicable period for each priority (step S310). Next, the calculation unit 105 calculates a communicable period corresponding to the number of connected devices for each priority (step S311). At present, the communication device 30 connected to the GW 10 is only one high priority device (communication device 30-1). Therefore, the calculation unit 105 calculates the communicable period of the communication device 30-1 by dividing the allocated communicable period by the number of high priority devices (for example, one). The calculation unit 105 allocates the communicable period calculated in the process of step S311 to the communication device 30-1. And the calculation part 105 records the value of the communicable period allocated to the communication apparatus 30-1 in the item of the communicable period of the record corresponding to the communication apparatus 30-1 among the records of a priority control table.

  The communication device 30-1 transmits a transmission permission request to the GW 10 (step S312). The first communication unit 101 receives the transmission permission request transmitted from the communication device 30-1. When the transmission permission request is received, the signal generation unit 106 generates a transmission permission response (step S313). When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period assigned to the communication device 30-1 that is the transmission source of the transmission permission request in the header of the transmission permission response. The first communication unit 101 transmits the generated transmission permission response to the communication device 30-1 (step S314).

The communication device 30-2 receives a beacon (high priority SSID) issued from the GW 10. The communication device 30-2 makes a probe request to the GW 10 for the SSID (high priority SSID) set in the own device (communication device 30-2) (step S315).
The first communication unit 101 of the GW 10 receives the probe request transmitted from the communication device 30-2. The connected terminal monitoring unit 104 refers to the priority control table and determines whether the probe-requested high priority SSID and the broadcast high priority SSID are the same. When the high-priority SSID requested for the probe and the broadcast high-priority SSID are the same, the first communication unit 101 makes a probe response to the communication device 30-2 (step S316). When the high priority SSID requested for the probe is different from the broadcast high priority SSID, the first communication unit 101 does not make a probe response.

  The communication device 30-2 receives the probe response transmitted from the GW 10. Upon receiving the probe response, the communication device 30-2 performs authentication with the GW 10. Specifically, the communication device 30-2 transmits a high priority SSID password to the GW 10 according to an authentication method (for example, a password) set in advance with the GW 10 (step S317). The first communication unit 101 receives the password of the high priority SSID transmitted from the communication device 30-2. The control unit 102 determines whether or not the received high priority SSID password matches a preset high priority SSID password. If the passwords match, the first communication unit 101 transmits a notification indicating the completion of authentication to the communication device 30-2. If the passwords are different, the first communication unit 101 transmits an error to the communication device 30-2 (step S318).

  When the authentication is completed, the communication device 30-2 transmits an association request to the GW 10 (step S319). The first communication unit 101 receives the association request transmitted from the communication device 30-2. The first communication unit 101 transmits an association response to the communication device 30-2 as a response to the received association request (step S320). Thereby, the connection between the GW 10 and the communication device 30-2 is completed.

  When the connection is completed, the control unit 102 records information (for example, MAC address) of the communication device 30-2 that has been connected in the priority control table. More specifically, the control unit 102 records information on the communication device 30-2 in a record of the priority control table corresponding to the SSID (high priority SSID) included in the received association request. The connected terminal monitoring unit 104 checks the number of communication devices 30 connected to the own device by referring to the priority control table (step S321).

  The calculation unit 105 calculates a communicable period for each priority, and assigns the calculated communicable period for each priority (step S322). Next, the calculation unit 105 calculates a communicable period corresponding to the number of connected devices for each priority (step S323). At present, there are two high-priority devices (communication devices 30-1 and 30-2) connected to the GW 10. Therefore, the calculation unit 105 calculates the communicable periods of the communication apparatuses 30-1 and 30-2 by dividing the allocated communicable period by the number of high priority apparatuses (for example, two). The calculation unit 105 assigns the communication possible period calculated in the process of step S323 to each of the communication devices 30-1 and 30-2. For example, the calculation unit 105 assigns a communicable period with a communication start time earlier than that of the communication device 30-2 to the communication device 30-1 with the earlier registered order. The calculation unit 105 records the value of the communicable period assigned to each of the communication devices 30-1 and 30-2 in the item of the communicable period of the record of the priority control table.

  The communication device 30-2 transmits a transmission permission request to the GW 10 (step S324). The first communication unit 101 receives the transmission permission request transmitted from the communication device 30-2. When the transmission permission request is received, the signal generation unit 106 generates a transmission permission response for the communication device 30-2 that is the transmission source of the transmission permission request (step S325). When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period assigned to the communication device 30-2 that is the transmission source of the transmission permission request in the header of the transmission permission response. The first communication unit 101 transmits the generated transmission permission response to the communication device 30-2 (step S326). The communication device 30-2 receives the transmission permission response transmitted from the GW 10. However, since the period indicated by the communicable period stored in the transmission permission response received by the communication apparatus 30-2 has not elapsed, the communication apparatus 30-2 waits until the communicable period elapses.

  The signal generation unit 106 generates a transmission permission response for the influence device (for example, the communication device 30-1) (step S327). When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period assigned to the communication device 30-1 in the header of the transmission permission response. The first communication unit 101 transmits the generated transmission permission response to the communication device 30-1 (step S328).

  The communication device 30-1 receives the transmission permission response transmitted from the GW 10. When it is a period indicated by the communicable period stored in the transmission permission response received by the communication device 30-1, the communicable period performs connection processing with the target server 20 via the GW 10 (step S329). . Thereafter, the communication device 30-1 communicates with the target server 20 during the communicable period (step S330). When the communicable period assigned to the communication device 30-2 is reached, the communication device 30-1 ends communication with the target server 20. Further, when the communicable period assigned to the communication device 30-2 is reached, the communication device 30-2 performs a connection process with the target server 20 via the GW 10 (step S331). Thereafter, the communication device 30-2 communicates with the target server 20 during the communicable period (step S334).

FIG. 10 is a flowchart showing the flow of processing for calculating the communicable time of the GW 10 in this embodiment. Note that FIG. 10 illustrates an example in which the GW 10 is operating in the second mode. Further, the processing similar to that in FIG. 6 is denoted by the same reference numerals as those in FIG.
When the processing up to the processing in step S103 is completed, the calculation unit 105 calculates a communicable period based on the communication state of the high priority device (step S401). Specifically, the calculation unit 105 calculates the value of the high-priority communicable period among the communicable periods assigned for each priority in the process of step S102 based on the communication state of the high-priority apparatus. The communication possible period is calculated. Thereafter, the calculation unit 105 assigns the communicable period calculated in the process of step S401 to each high priority device. The calculation unit 105 records the value of the communicable period assigned to each high priority device in the priority control table.

  Further, the connected terminal monitoring unit 104 refers to the priority control table and confirms the number of medium priority devices (step S402). The calculation unit 105 calculates a communicable period based on the communication state of the medium priority device (step S403). Specifically, the calculation unit 105 calculates the value of the medium-priority communicable period among the communicable periods assigned for each priority in the processing of step S102 based on the communication state of the medium-priority apparatus. The communication possible period is calculated. Thereafter, the calculation unit 105 assigns the communicable period calculated in the process of step S403 to each medium priority device. The calculation unit 105 records the value of the communicable period assigned to each high priority device in the priority control table.

  Further, the connected terminal monitoring unit 104 refers to the priority control table and checks the number of low priority devices (step S404). The calculation unit 105 calculates a communicable period based on the communication state of the low priority device (step S405). Specifically, the calculation unit 105 calculates the value of the low-priority communicable period among the communicable periods assigned for each priority in the process of step S102 based on the communication state of the low-priority apparatus. The communication possible period is calculated. Thereafter, the calculation unit 105 allocates the communicable period calculated in the process of step S405 to each low priority device. The calculation unit 105 records the value of the communicable period assigned to each low priority device in the priority control table.

  11 and 12 are sequence diagrams showing the operation of the priority control system 100 in the present embodiment. In FIGS. 11 and 12, a case where the GW 10 operates in the second mode will be described as an example. 11 and 12, the main communication of the communication device 30-1 is SIP (Session Initiation Protocol) communication, and the main communication of the communication device 30-2 is HTTP (Hyper Text Transfer Protocol) communication. 8 and 9 are denoted by the same reference numerals as in FIGS. 8 and 9 and will not be described.

  When the processing up to step S310 ends, the calculation unit 105 calculates a communicable period for each priority based on the communication state (step S501). At present, the communication device 30 connected to the GW 10 is only one high priority device (communication device 30-1). Therefore, the calculation unit 105 calculates the communicable period of the communication device 30-1 by distributing the allocated communicable period based on the communication state of the high priority apparatus. The calculation unit 105 assigns the communication possible period calculated in the process of step S501 to the communication device 30-1. And the calculation part 105 records the value of the communicable period allocated to the communication apparatus 30-1 in the item of the communicable period of the record corresponding to the communication apparatus 30-1 among the records of a priority control table.

  The communication device 30-1 transmits a transmission permission request to the GW 10 (step S502). The first communication unit 101 receives the transmission permission request transmitted from the communication device 30-1. When the transmission permission request is received, the signal generation unit 106 generates a transmission permission response (step S503). When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period assigned to the communication device 30-1 that is the transmission source of the transmission permission request in the header of the transmission permission response. The first communication unit 101 transmits the generated transmission permission response to the communication device 30-1 (step S504).

The communication device 30-2 receives a beacon (high priority SSID) issued from the GW 10. The communication device 30-2 makes a probe request to the GW 10 for the SSID (high priority SSID) set in the own device (communication device 30-2) (step S505).
The first communication unit 101 of the GW 10 receives the probe request transmitted from the communication device 30-2. The connected terminal monitoring unit 104 refers to the priority control table and determines whether the probe-requested high priority SSID and the broadcast high priority SSID are the same. When the high-priority SSID requested for the probe and the broadcast high-priority SSID are the same, the first communication unit 101 makes a probe response to the communication device 30-2 (step S506). When the high priority SSID requested for the probe is different from the broadcast high priority SSID, the first communication unit 101 does not make a probe response.

  The communication device 30-2 receives the probe response transmitted from the GW 10. Upon receiving the probe response, the communication device 30-2 performs authentication with the GW 10. Specifically, the communication device 30-2 transmits the password of the high priority SSID to the GW 10 in accordance with an authentication method (for example, password) set in advance with the GW 10 (step S507). The first communication unit 101 receives the password of the high priority SSID transmitted from the communication device 30-2. The control unit 102 determines whether or not the received high priority SSID password matches a preset high priority SSID password. If the passwords match, the first communication unit 101 transmits a notification indicating the completion of authentication to the communication device 30-2. If the passwords are different, the first communication unit 101 transmits an error to the communication device 30-2 (step S508).

  When the authentication is completed, the communication device 30-2 transmits an association request to the GW 10 (step S509). The first communication unit 101 receives the association request transmitted from the communication device 30-2. The first communication unit 101 transmits an association response as a response to the received association request to the communication device 30-2 (step S510). Thereby, the connection between the GW 10 and the communication device 30-2 is completed.

  When the connection is completed, the control unit 102 records information (for example, MAC address) of the communication device 30-2 that has been connected in the priority control table. More specifically, the control unit 102 records information on the communication device 30-2 in a record of the priority control table corresponding to the SSID (high priority SSID) included in the received association request. The connected terminal monitoring unit 104 checks the number of communication devices 30 connected to the own device by referring to the priority control table (step S511).

  The calculation unit 105 calculates a communicable period for each priority, and assigns the calculated communicable period for each priority (step S512). Next, the calculation unit 105 calculates a communicable period for each priority based on the communication state of the communication device 30 connected to the own device (step S513). At present, there are two high-priority devices (communication devices 30-1 and 30-2) connected to the GW 10. The calculating unit 105 calculates the communicable periods of the communication apparatuses 30-1 and 30-2 by apportioning the allocated communicable period based on the communication state of the high priority apparatus. The calculation unit 105 allocates the communicable period calculated in step S513 to each of the communication devices 30-1 and 30-2. For example, since the communication of the communication device 30-1 is SIP communication and the communication of the communication device 30-2 is HTTP communication, the calculation unit 105 causes the communication device 30-1 to start communication more than the communication device 30-2. Allocate an early communication period. The calculation unit 105 records the value of the communicable period assigned to each of the communication devices 30-1 and 30-2 in the item of the communicable period of the record of the priority control table.

  The communication device 30-2 transmits a transmission permission request to the GW 10 (step S514). The first communication unit 101 receives the transmission permission request transmitted from the communication device 30-2. When the transmission permission request is received, the signal generation unit 106 generates a transmission permission response for the communication device 30-2 that is the transmission source of the transmission permission request (step S515). When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period assigned to the communication device 30-2 that is the transmission source of the transmission permission request in the header of the transmission permission response. The first communication unit 101 transmits the generated transmission permission response to the communication device 30-2 (step S516). The communication device 30-2 receives the transmission permission response transmitted from the GW 10. However, since the period indicated by the communicable period stored in the received transmission permission response has not elapsed, the communication device 30-2 waits until the period elapses.

  The signal generation unit 106 generates a transmission permission response for the affected device (for example, the communication device 30-1) (step S517). When generating the transmission permission response, the signal generation unit 106 stores the value of the communicable period assigned to the communication device 30-1 in the header of the transmission permission response. The first communication unit 101 transmits the generated transmission permission response to the communication device 30-1 (step S518).

  The communication device 30-1 receives the transmission permission response transmitted from the GW 10. Since this is the period indicated by the communicable period stored in the transmission permission response received by the communication device 30-1, the communication device 30-1 transmits an INVITE message to the target server 20 via the GW 10 (step S519). . Thereafter, when a session is established between the communication device 30-1 and the target server 20, the communication device 30-1 transmits / receives RTP to / from the target server 20 during the communicable period (step S520). When the communicable period assigned to the communication device 30-2 is reached, the communication device 30-1 ends communication with the target server 20. Further, when the communicable period assigned to the communication device 30-2 is reached, the communication device 30-2 performs a connection process with the target server 20 via the GW 10 (step S521). Thereafter, the communication device 30-2 communicates with the target server 20 during the communicable period (step S522).

FIG. 13 is a sequence diagram showing a specific operation of the priority control table setting change process in the present embodiment.
The operator terminal 40 is connected to the GW 10 by being operated by a GW related person, and requests setting registration screen data (step S601). The first communication unit 101 of the GW 10 receives a request for setting registration screen data from the operator terminal 40 (step S602). In response to the request, the control unit 102 acquires the setting registration screen data stored in the setting registration screen data storage unit 109 (step S603). The first communication unit 101 transmits the acquired setting registration screen data to the operator terminal 40 (step S604).

  The operator terminal 40 receives setting registration screen data from the GW 10. The operator terminal 40 displays the received setting registration screen data (step S605). The operator terminal 40 receives an input of the setting content of the priority control information of the GW 10 when operated by a GW related person (step S606). When the input of the setting content by the GW related person is completed, the operator terminal 40 generates setting registration information, and transmits the generated setting registration information to the GW 10. Information of setting contents is stored in the setting registration information (step S607).

  The first communication unit 101 receives the setting registration information transmitted from the GW 10 (step S608). The control unit 102 updates each item (priority, communication ratio, SSID) in the priority control table by overwriting with the value of each item set by the GW related person according to the received setting registration information (step S609). ). In addition, the control unit 102 updates the setting registration screen data. Further, the control unit 102 determines the operation mode of the own apparatus according to the operation mode information included in the setting registration information. When the update of the priority control table is completed, the first communication unit 101 transmits a notification indicating the completion of setting to the operator terminal 40 (step S610).

  According to the priority control system 100 configured as described above, the GW 10 secures a communicable period for each priority based on the communication ratio, and then the number or communication state of the communication devices 30 connected to the own device. Accordingly, a communicable period for each communication device 30 is calculated and assigned to each communication device 30. Thereby, each communication apparatus 30 transmits data only during the allocated communicable period. Therefore, even when a plurality of SSIDs are set in an environment that interferes with each other, a period in which communication can be performed is assigned to each communication device 30, and therefore, the possibility of interference with signals of other communication devices is reduced. Is done. In addition, since the communication device 30 of the GW related party can be connected to the high priority SSID, the communication device 30 of the external user has priority over the communication device 30 of the external user. Therefore, even when a plurality of SSIDs are used in an environment where they interfere with each other, priority control for each SSID is possible.

<Modification>
A plurality of target servers 20 may be connected to the priority control system 100. A plurality of communication devices 30 may be connected to the priority control system 100. A plurality of operator terminals 40 may be connected to the priority control system 100.
The setting registration screen may be displayed on the communication device 30.
Information on the communicable period may be stored in the payload.
In the present embodiment, the number of priorities registered in the priority control table is three, but it is not necessary to be limited to this. For example, four or more priorities may be registered in the priority control table, and two priorities (for example, high priority and low priority) may be registered.

When the number of communication devices 30 connected to the GW 10 is one, the GW 10 allocates a communicable period for a predetermined period (for example, 1 second) regardless of the priority of the connected communication device 30. May be configured.
With this configuration, a communicable period can be assigned to the communication device 30 that can communicate regardless of the priority. Therefore, it becomes possible to improve the communication efficiency of the communication device 30 connected to the GW 10.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 ... GW, 20 ... Target server, 30 (30-1 to 30-N) ... Communication device, 40 ... Operator terminal, 50 ... Network, 101 ... First communication unit, 102 ... Control unit, 103 ... Priority control information storage Reference numeral 104, Connection terminal monitoring unit, 105 ... Calculation unit, 106 ... Signal generation unit, 107 ... Second communication unit, 108 ... Relay unit, 109 ... Setting registration screen data storage unit

Claims (5)

A relay device that uses multiple network identifiers in an environment that interferes with each other,
A calculation unit that calculates a communicable period for each communication device connected to the network identifier set for each priority based on a ratio of a communicable period in a predetermined period set for each priority;
A generating unit that generates a control signal using the calculated communicable period;
A transmission unit for transmitting the generated control signal to the communication device;
A relay device comprising:   The calculation unit calculates a communicable period for each priority by multiplying the predetermined period and the communicable ratio, and calculates the communicable period calculated for each priority for each priority. The relay device according to claim 1, wherein the communication possible period for each communication device is calculated for each priority by dividing by the number of connected communication devices.   The calculation unit calculates a communicable period for each priority by multiplying the predetermined period and the communicable ratio, and calculates the communicable period calculated for each priority for each priority. The relay device according to claim 1, wherein a communicable period for each communication device is calculated for each priority based on a communication state of the communication device. A priority control method in a relay apparatus that uses a plurality of network identifiers in an environment that interferes with each other,
A calculation step of calculating a communicable period for each communication device connected to the network identifier set for each priority based on a ratio of a communicable period in a predetermined period set for each priority;
A generation step of generating a control signal using the calculated communicable period;
A transmission step of transmitting the generated control signal to the communication device;
A priority control method. A computer program in a relay device that uses a plurality of network identifiers in an environment that interferes with each other,
A calculation step of calculating a communicable period for each communication device connected to the network identifier set for each priority based on a ratio of a communicable period in a predetermined period set for each priority;
A generation step of generating a control signal using the calculated communicable period;
A transmission step of transmitting the generated control signal to the communication device;
A computer program for causing a computer to execute.

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